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diff --git a/Documentation/mm/page_tables.rst b/Documentation/mm/page_tables.rst index 7840c18917..be47b192a5 100644 --- a/Documentation/mm/page_tables.rst +++ b/Documentation/mm/page_tables.rst @@ -152,3 +152,130 @@ Page table handling code that wishes to be architecture-neutral, such as the virtual memory manager, will need to be written so that it traverses all of the currently five levels. This style should also be preferred for architecture-specific code, so as to be robust to future changes. + + +MMU, TLB, and Page Faults +========================= + +The `Memory Management Unit (MMU)` is a hardware component that handles virtual +to physical address translations. It may use relatively small caches in hardware +called `Translation Lookaside Buffers (TLBs)` and `Page Walk Caches` to speed up +these translations. + +When CPU accesses a memory location, it provides a virtual address to the MMU, +which checks if there is the existing translation in the TLB or in the Page +Walk Caches (on architectures that support them). If no translation is found, +MMU uses the page walks to determine the physical address and create the map. + +The dirty bit for a page is set (i.e., turned on) when the page is written to. +Each page of memory has associated permission and dirty bits. The latter +indicate that the page has been modified since it was loaded into memory. + +If nothing prevents it, eventually the physical memory can be accessed and the +requested operation on the physical frame is performed. + +There are several reasons why the MMU can't find certain translations. It could +happen because the CPU is trying to access memory that the current task is not +permitted to, or because the data is not present into physical memory. + +When these conditions happen, the MMU triggers page faults, which are types of +exceptions that signal the CPU to pause the current execution and run a special +function to handle the mentioned exceptions. + +There are common and expected causes of page faults. These are triggered by +process management optimization techniques called "Lazy Allocation" and +"Copy-on-Write". Page faults may also happen when frames have been swapped out +to persistent storage (swap partition or file) and evicted from their physical +locations. + +These techniques improve memory efficiency, reduce latency, and minimize space +occupation. This document won't go deeper into the details of "Lazy Allocation" +and "Copy-on-Write" because these subjects are out of scope as they belong to +Process Address Management. + +Swapping differentiates itself from the other mentioned techniques because it's +undesirable since it's performed as a means to reduce memory under heavy +pressure. + +Swapping can't work for memory mapped by kernel logical addresses. These are a +subset of the kernel virtual space that directly maps a contiguous range of +physical memory. Given any logical address, its physical address is determined +with simple arithmetic on an offset. Accesses to logical addresses are fast +because they avoid the need for complex page table lookups at the expenses of +frames not being evictable and pageable out. + +If the kernel fails to make room for the data that must be present in the +physical frames, the kernel invokes the out-of-memory (OOM) killer to make room +by terminating lower priority processes until pressure reduces under a safe +threshold. + +Additionally, page faults may be also caused by code bugs or by maliciously +crafted addresses that the CPU is instructed to access. A thread of a process +could use instructions to address (non-shared) memory which does not belong to +its own address space, or could try to execute an instruction that want to write +to a read-only location. + +If the above-mentioned conditions happen in user-space, the kernel sends a +`Segmentation Fault` (SIGSEGV) signal to the current thread. That signal usually +causes the termination of the thread and of the process it belongs to. + +This document is going to simplify and show an high altitude view of how the +Linux kernel handles these page faults, creates tables and tables' entries, +check if memory is present and, if not, requests to load data from persistent +storage or from other devices, and updates the MMU and its caches. + +The first steps are architecture dependent. Most architectures jump to +`do_page_fault()`, whereas the x86 interrupt handler is defined by the +`DEFINE_IDTENTRY_RAW_ERRORCODE()` macro which calls `handle_page_fault()`. + +Whatever the routes, all architectures end up to the invocation of +`handle_mm_fault()` which, in turn, (likely) ends up calling +`__handle_mm_fault()` to carry out the actual work of allocating the page +tables. + +The unfortunate case of not being able to call `__handle_mm_fault()` means +that the virtual address is pointing to areas of physical memory which are not +permitted to be accessed (at least from the current context). This +condition resolves to the kernel sending the above-mentioned SIGSEGV signal +to the process and leads to the consequences already explained. + +`__handle_mm_fault()` carries out its work by calling several functions to +find the entry's offsets of the upper layers of the page tables and allocate +the tables that it may need. + +The functions that look for the offset have names like `*_offset()`, where the +"*" is for pgd, p4d, pud, pmd, pte; instead the functions to allocate the +corresponding tables, layer by layer, are called `*_alloc`, using the +above-mentioned convention to name them after the corresponding types of tables +in the hierarchy. + +The page table walk may end at one of the middle or upper layers (PMD, PUD). + +Linux supports larger page sizes than the usual 4KB (i.e., the so called +`huge pages`). When using these kinds of larger pages, higher level pages can +directly map them, with no need to use lower level page entries (PTE). Huge +pages contain large contiguous physical regions that usually span from 2MB to +1GB. They are respectively mapped by the PMD and PUD page entries. + +The huge pages bring with them several benefits like reduced TLB pressure, +reduced page table overhead, memory allocation efficiency, and performance +improvement for certain workloads. However, these benefits come with +trade-offs, like wasted memory and allocation challenges. + +At the very end of the walk with allocations, if it didn't return errors, +`__handle_mm_fault()` finally calls `handle_pte_fault()`, which via `do_fault()` +performs one of `do_read_fault()`, `do_cow_fault()`, `do_shared_fault()`. +"read", "cow", "shared" give hints about the reasons and the kind of fault it's +handling. + +The actual implementation of the workflow is very complex. Its design allows +Linux to handle page faults in a way that is tailored to the specific +characteristics of each architecture, while still sharing a common overall +structure. + +To conclude this high altitude view of how Linux handles page faults, let's +add that the page faults handler can be disabled and enabled respectively with +`pagefault_disable()` and `pagefault_enable()`. + +Several code path make use of the latter two functions because they need to +disable traps into the page faults handler, mostly to prevent deadlocks. |